Milking process



Nov. 4, 1952 Filed May 16, 1949 R. R. GRAVES MILKING PROCESS 6 Sheets-Sheet 1 Nov. 4, 1952 R. R. GRAVES MILKING PROCESS 6 Sheets-Sheet 2 Filed May 16, 1949 i INVENTOR.

Nov. 4, 1952 v R. R. GRAVES ,616,

MILKING PROCESS Filed May 16, 1949 6 Sheets-Sheet 3 Nov. 4, 1952 R. R. GRAVES 2,616,809

MILKING PROCESS Filed May 16, 1949 6 Sheets-Sheet 4 22.; 224 22 o IN VEN TOR. 26 ffi fiyflwa Nov. 4, 1952 R. R. GRAVES 2,616,809

MILKING PROCESS Filed May 16, 1949 6 Sheets-Sheet 5 IN VEN TOR.

Nov. 4, 1952 R. R. GRAVES 6,

- MILKING PROCESS Filed May 16, 1949 e Sheets-Sheet e I N VEN TOR.

Patented Nov. 4,

MILKING PROCESS Roy R. Graves, Valparaiso, Ind., assignor, by

direct and mesne assignments, to The Graves- Stambaugh Corporation, a corporation of Delaware Application May 16, 1949, Serial No. 95,225

20 Claims.

' This invention is directed to a method and apparatus for processing milk and this application is a continuation in part of my co-pending application Ser. No. 781,602 filed October 23, 1947.

The present day procedure in commercially handling and processing milk is quite standard. The cows are milked at each farm in the morning and at night, and'the raw milk at each milking is promptly cooled from body temperature to 55 or 60 F. or lower. The night milking is usually stored at the lowered temperature over night and then it. and the cooled morning milking are both delivered to a processing plant or to a station where it is reshipped to the processing plant. During the shipment of the milk to the shipping station there is normally a considerable rise in temperature which requires the milk to again be cooled before shipment to the processing plant and often it is again cooled at the processing plant so that it may be safely stored until it is processed. During the milking, cooling and storing at the farms, the shipping, and the cooling and storing at the processing plant, the

raw milk is in contact with air, is subject to cooling and heating over relatively wide temperature ranges and is agitated considerably during handling all of which results in oxygen absorption and lypolytic action.

Inthe present day commercial processing of milk, the cooled stored raw milk received from the farms is first pasteurized by passing the raw milk through apasteurizer which heats the milk to pasteurizing temperatures, various types of pasteurizers being used. The pasteurized milk is then cooled and bottled. If the milk is to be homogenized, it is passed through a homogenizer after it has been pasteurized. Here again, in the storing, pasteurizing, homogenizing, cooling and bottling steps, the milk is in contact with air and the milk tends to reach an oxygen equilibrium with that of the atmosphere.

Milk and cream commercially processed in the foregoing manner, while probably meeting sanitation requirements, definitely are lacking in certain qualities. Their flavor and palatability are considerably less than what they could be. Such milk and cream have 01f flavors such as rancid, tallowy, cardboardy, cowy and cooked or pasteurized flavors. They have a leucocyte sludge that necessitates clarification steps to remove it. There is a visible separation of cream layers after standing even when homogenized. When cream is placed in coffee feathering usually occurs because of its low heat stability. Acidity developes rapidly in such milk and cream turning the same sour rather quickly even under refrigeration. They have low heat stability and will tend to coagulate when exposed to high temperatures. They cannot be successfully canned for long time preservation. Vitamin C concentration is quickly lost.

Generally, these deficiencies in milk and cream commercially processed in the foregoing manner are brought about by absorption of oxygen by the milk during its cooling in the presence of air; by enzymic action instigated by cooling and warming before pasteurization; by bacterial action due to high bacterial content; by homogenization of the milk at high temperatures following pasteurization and by improper methods of pasteurization in which milk is exposed to high temperatures for considerable periods of time and without turbulence during the exposure.

The principal object of this invention is to provide an improved method and apparatus for processing milk wherein the resultant milk and cream have qualities heretofore unobtainable in pasteurized milk and cream, wherein off flavors such as rancid, tallowy, cowy and cooked or pasteurized flavors are substantially eliminated, wherein leucocyte sludge is substantially eliminated without clarification, wherein there is no visible separation of cream layers in homogenized milk even after long standing, wherein there is no feathering of cream when placed in coifee, wherein there is substantially no development of acidity over long periods of time, wherein the milk and cream will have high heat stability substantially to prevent coagulation and high viscosity when exposed to high temperatures, wherein milk and cream can be successfully canned for long time preservation either with or without refrigeration, and wherein the vitamin C concentration may be maintained over long periods of time.

The method of this invention for processing milk to produce the aforementioned advantageous results includes generally the steps of withdrawing from a cow raw milk aseptically and without contact with air, collecting the withdrawn raw milk without contact with air and maintaining the same at substantially body temperature, homogenizing the collected raw milk without substantial prior cooling and without contact with air, and promptly and rapidly heating the homogenized milk without contact with air at least to pasteurization temperatures. The pasteurized or heat treated milk may then be bottled or hermetically sealed in containers or further processed in any desired manner. When the homogenized milk is heated to sterilization temperatures it may be safety stored in hermetically sealed containers, such as cans, without refrigeration for substantially indefinite periods of time. In this respect the homogenized milk may be heated to sterilization temperatures before it is aseptically canned without contact with air or it may be heated to sterilization temperatures in the cans, the former being preferable.

By maintaining the raw milk out of contact with air and at substantially body temperature from the time it is withdrawn from the cow until it is heated at least to pasteurization temperatures, bacterial growth is substantially inhibited, oxidation is substantially prevented, the butterfat globules of the milk are kept in liquid form and enzymatic reaction of lipase is held to a minimum. These factors are of prime import ance in the production of milk and cream having the aforementioned desirable and advantageous qualities.

It is found that there is substantially no bacterial growth in the raw milk kept at substantially body temperature and out of contact with air for a period of three hours or so, and that the becteria count of milk processed in accordance with his invention is considerably less than that of milk processed in accordance with present day commercial practices. Keeping the raw milk out of contact with air also prevents contamination by air borne bacteria andfurther prevents absorption of oxygen and hence oxidation of the milk. The prevention of oxygen absorption of the raw milk, and of the milk in subsequent processing, prevents oxidation changes in the milk and its constituents that lead to lowered heat stability and to the development of undesirable flavors.

Because the raw milk is maintained at substantially body temperature out of contact with air before heating at least t pasteurization temperatures, the butterfat globules remain liquid instead of becoming solid or clumped as in present day practice Where the raw milk is substantially cooled before pasteurization. This is one of the factors which maintains the enzymatic action of lipase at a minimum to provide a pasteurized milk which may be safely stored over long periods of time, which prevents the formation of off flavors such as rancid and tallowy, which permits thorough pasteurization of the milk, which provides the milk with heat stability, and which permits more thorough homogenization without the formation of leucocyte sludge or sediment. Because oxidation and acidification of the milk processed in accordance with this invention are retarded or inhibited, the vitamin concentration is maintained over long periods of time.

There are at least four grades of milk that may be produced by the method and apparatus of this invention, the differences being due to the degree of heat treatment applied and the method of packaging. In all instances, however, the method and apparatus for aseptically withdraw- 4 ing the milk from the herd, handling, homogenizing and pasteurizing or sterilizing are the same.

In the first grade of milk and cream, A class, it will be homogenized and pasteurized at 161 F. and packaged in glass or paper cartons in the presence of air. Kept under refrigeration and without undue exposure to light this milk and cream have the following characteristics that distinguish them from other milks and creams; they have so little pasteurization flavor that many believe them to be raw milk and cream; they have no leucocyte sludge even without clari'fication; they have no visible separation of cream layers even after long standing; they have a high heat stability and do not feather in coffee; they do not develop rancid, tallowy or cowy flavors; and there is no development of acidity for a period of more than two weeks when kept under refrigeration.

The next grade is a super-pasteurized milk or cream that is homogenized and pasteurized at F. or above and packaged in glass or in tin either in a vacuum or in an inert gas such as nitrogen or carbon dioxide. When packed in gas they are processed and packaged under positive gas pressure and they are discharged into the filling chamber of the packaging machine while still warm in order to effect a still further reduction in the oxygen content. Kept under refrigeration and without undue exposure to light they will have substantially the characteristics of the first grade of milk. Further, they will keep for periods of from two to four weeks with? out developing rancid, tallowy or cowy flavors or without development of acidity.

The third grade is a sterile milk or cream that is homogenized and packaged in tin either in a vacuum or in an inert gas. They are processed in the same manner as the super-pasteurized milk and cream except that they are packaged in tins, and therefore, are not exposed to light. Furthermore, the milk is raised to sterilization temperature, either before the milk is aseptically placed in the tins or after it is sealed in the tins. The characteristics of this milk and cream are substantially the same as those of the other grades. In, addition, however, this milk and cream can be kept for indefinite periods without refrigeration and Will not develop rancid, tallowy or cowy flavors even though no preservative, stabilizer or antioxidant has been added.

The fourth grade is a milk and cream processed for manufacturing purposes and the same process is utilized as in the super-pasteurized grade. It may or may not be homogenized depending upon the productto be made. It has the same general qualities as discussed above. Because of its extremely low oxygen content and absence of lipolytic action this milk is ideal for the manufacture of dried whole milk or dried cream where great difficulties have been experienced in the development of rancid Or oxidized flavors in the finished product. It is also ideal for the manufacture of special baby foods because of its low bacterial content and soft curd. Because it has not had its physical character altered by enzymatic action due to the cooling and warming of the fat globules, it, therefora possesses all the natural flavors and is ideal for the manufacture of any dairy product where excellence of flavor is essential Further objects of this invention reside in the specific steps of the method and the relationship between such steps, and also, in the construction of the apparatus for performing the method of this invention includingthe details'of' construction and the cooperative relationship between the component parts of the apparatus.

Other objects and advantages will become apparent to those skilled 'in the art upon reference to the accompanying specification; claims and drawings in which:

Figure 1 is a diagrammatic view illustrating a milking machine, weigh jar and receiving tank operatively associated for performing the first portion of the method of this invention;

Figure 2 is a diagrammatic illustration of a receiving tank, homogenizer and pasteurizer and the cooperative relationship therebetween for performing another portion of the *method of this invention; l

Figure 3 is a diagrammatic view of'a portable receiving tank which may be utilized in the method of this inventionp Figure 4 is a diagrammatic illustration of the pre -heater and pasteurizer showing the'manner in which the's'ame are supplied with steam;

Figure 5 is a detail view of a valve incorporated in the milking machine; a l

Figure 6 is a vertical sectional view through the pasteurizer;

Figures '7 and dare illustrations of the claw and teat cups of the milking machine shown to be located in different positions;

- Figure 9 is a diagrammatic view similar to Fig. 2, but illustrating a difierent arrangement for pre-hea-ting thehomogenized milk and coolin the pasteurized milk;

Figure 10 is an elevation of a regenerator, and Figure 11 is a diagrammatic view similar to Fig. 9 butillustrating a different manner of pasteurizing and sterilizing the milk;

In my co-pending application Ser. No. 781,602-

vided with four nipples l2, each'having an an-- Each nipple is connected by a rubber tube It to the metal shell of a teat cup gular end l3.

l5 which is internally provided with a rubber sleeve l6 adapted intermittently'to compress the teat ll of the cows udder IS. The metal shell l5 of each teat cup is provided with a nipple l9, each of which are connected by rubber tubes to a manifold 21 secured at 22 to the manifold II. The manifold 21 is'provided with an eye 23 so that the claw maybe suspended by a hook 24 received in the eye 23 as illustrated in Fig. '8.

The manifold H is provided with a valve casing 25 for receiving a .valve ZSoperate'd by a handle 21, as is clearly illustrated in Fig. 5. The valvecasing 25 opens into the manifold II at 28 and is provided with a suction opening 29 communicating with a fitting 30. The valve casing 25 is also provided with a vent port 3l. The plug 25 has a milk passage 32 which connects the manifold II. with the fitting 30 when'the valve plug is in the position illustrated in Fig.

5. When; hbwever, the-valve plug is rotated 6 clockwise througha quarter of a turn the com munication between the manifold H and the fitting 30 is broken, the fitting is sealed off and communication is established between the mamfold II and the vent port 3| by the passage 33. Valve 26 may be located any place in line 62 intermediate the manifold II and weigh jar 5|, but in that case manifold ll would have a hose fitting at the end where valve 26 is attached and valve 26 would require an additional hose fitting at 32; or if more convenient for operation valve 26 may be attached to the weigh jar at the point where 62 and El join. In any of these three 10- cations valve 26 accomplishes the same purpose, that is, it breaks the vacuum in manifold ll, tubes l4, and inner liner l6, permitting the teat cups to drop off the teats without admitting air to the weigh jar 5|, at the end of the milking op eration.

A vacuum pump 35 driven by a motor 35 is connected to a vacuum line 3! which in turn may be connected to all of the milking machines and Weigh jars utilized. The vacuum line 31 is associated with the milking machine In through a valve 38. The valve is connected by a rubber tubing 39 to a T fitting 4B which in turn is connected by a tube M to a pulsator 42. The pulsator 42 is connected by tubes 43 and 44 to nipples 45 and 46, respectively, communicating with the manifold 2| of the milking machine. The pulsator 42 operates intermittently to place vacuum on the tube 43 and atmospheric pressure on the tube 44 alternately. Thus, the pressure in the manifold 2| is alternately changed from vacuum to atmospheric pressure to expand and contract the rubber sleeves I6 of the teat cups to produce the milking action.

The other leg of the T fitting 40 is connected by a tube 48 to a nipple 49 secured in the cover 50 of the weigh jar 5|. The weigh jar includes a transparent bottle 52 sealed to the cover 50 by a gasket 53 and to a base 55 by a gasket 54. Tie rods 58, a frame 5! and an adjusting screw 58 maintain the cover 50, the weigh jar 52 and base 55 in assembled and sealed relation. The weigh jar 5! may be supported on a suitable scale by a bail 59. The base 55 carries a tube 6| which is connected by a tube 62 to the fitting 30 of the claw of the milking machine.

Thus, the vacuum pump 35 produces a vacuum in the weigh jar 5i and through the tubes 6i and 62 produces a vacuum in the manifold II which is communicated to the interior of the teat cups by-the tubes I4. As the cow is milked by the action of the pulsator 42 the milk is drawn by vachugs the. base of the teat so tightly during the milking operations that the amount of air admitted around the teat during the milking is infinitesimal and, any air that might thus be admitted is promptly sucked out by the action of the vacuum.

When the milking of the cow is completed the valve plug 26 is rotated through one quarter of a turn whereby the vacuum connection between the claw of the milking machine and the weigh jar is closed off so thatthe vacuum is retained in the-weigh jar. Atthe same-time the teat cupsare vented to atmosphere so that they may be. removed from the cow. Themilking-machine is then hung in the inverted position as illustrated in Fig. 8 and'may be, cleaned with water and a suitable antiseptic before it is attached to the next cow to bemilked.

When the next cow is to be milked, the milking machine is rotated from the inverted position to the normal position as illustratedin Fig. 7 with the teat cups hanging downwardly as is shown. The rubber tubes M then overlie, the angular ends of the nipples l2 and act as a valve means for sealing off the nipples. The valve plug is then rotated to the position illustrated in Fig. 5 to establish the vacuum in the manifold II. This vacuum will not be broken because-of the, valve action of the ends of the nipples l2. As each teat cup is elevated and placed upon the cow, the respective tubes l4 uncover the ends of the nipples l2 so that the vacuum in the manifold H is individually communicated with each teat cup as it is applied to the cow. In this, way an effective vacuum seal is provided to prevent breaking of the vacuum in the weigh jar at the beginning of each milking operation. This keeps the milk out of contact with air since it is drawn from the teat into a vacuum that exists throughout its passage from the liner [6 to the weigh jar 5i and from the weigh jar 51 into the vacuum tank 65. Of course, the milk iswithdrawn from the weigh jar 5| between each milking operation.

A receiving tank 65 is adapted to receive milk from the various weigh jars. It may be supported by suitable legs 66. The top of the receiving tank may be provided with a suitable manhole 61 which is normally sealed shut, but which may be opened for the purpose of cleaning the interior of the tank 65. A vacuum is produced in the tank 65 by a vacuum connection 68 leading from a vacuum pump 69 driven by a suitable motor 16. A vacuum may be maintained in this tank by means of a steam jet vacuum apparatus, if so desired. Preferably, the vacuum retained in the tank 65 is between and in., there thus being a differential in vacuum between the tank 65 and the weigh jar 5|. A milk line ll enters the top of the tank 65 and may be provided with a suitable strainer ?2 held in place by a ring 13. It is found that a flannel sock with the nap on the inside is a very effective strainer and successfully strains all foreign matter which might be present in the milk such as scurf from the exterior of the teats and the like. The milk line I! is connected through a valve 13 and a tube 14 to a nipple l5 entering.

the bottom of the'weigh jar 5|. Thus, when the valve 53 is opened milk is withdrawn from the weigh jar 5| into the receiving tank 65 by reasonof the differential in vacuum existing therebetween. It is, therefore, not necessary to break the vacuum in the weigh jar to withdraw milk therefrom into the receiving tank. In this way the milk is kept out of contact with air.

While the milk may be withdrawn directly from the milking machine Iii into the receiving tank 65, it is desirable to interpose the weigh jar 51. By reason of the weigh jar 5! it is possible to weigh the milking of each cow in order tokeep accurate records of milk production and the weigh jar also provides a ready means for inspecting the milking of each cow before the same is joined with the milkingsof other cows the receiving tank. For example, if a blood vessel in zthe-udder-of ;a cow were ruptured so asto'discolor the, milkjfrom that cow, it would be readilydetected in the weigh jar and would not be transmitted to the receiving tank. In this way discoloration of the entire milking of the here]. is efl'ectively prevented.

In the event that it is desired to withdraw and dispose of the milking in the weigh jar 5| the vacuum in the weigh jar may be broken by closing valve Y38 and removing the teat cups from the-icow'in the manner mentioned above by rotating the valve plug 2-6 and thenrotating the valve plug (Fig 5) anadditional quarter revolution so that the passage 33 establishes communication between-the manifold I I and the fitting 30-. Thus; air may enter the weigh jar through the teat cups, the manifold and tubes 62 and 6| because the teat cups are not on the cow. The tube 14 isthen disconnected from the valve 13 i and the milk drained from-:theweigh jar therethrough; The tube '14 may then be replaced on thevalve 13' and-the weigh jar 5| may be washed and rinsed with water and a chlorine solution by placing the tea-tcups in apail of water and chlorine solution and establishing the vacuum connection between the teat cups and the weigh jar. After the weigh jar has been rinsed and filled with'water and chlorine, it may be drained from the weigh jar in the same manner that the discolored milk was drained therefrom.

If. it is desired to take milkor cream that is to be processed into tank 65, suitable connections can be made to" the receptacle in which they are contained, through valve 11. When valve- 16 is r closed: and 1-1 isopened, the milk or cream will be The-receiving tank-65 may be provided with a suitable agitator driven by a motor 8| for keeping. the milk in' the receiving tank in motion to prevent formation of cream layers. Milk may be w-ithdraw-nfrom thereceiving tank 65 through connections 63 and B l-controlled by valves and 86respectively. The connection 83 may lead to the homogenizing a-nd-pasteurizing apparatus illustrated in Figs. 2 and 9', and connection 84 maylead to some other processing equipment if different processing is desired.

The receiving tankmaybe cleaned and sterilized by inserting water and steam therein through apipe 81- connected-to valves 88 and 69 controlling the supply of water and steam, respectively. To clean and sterilize the milk line 'H- and the weigh jar, valve 16 in the milk line may beopened and valve H may be closed. In this way steam admitted to tank 65'through valve 89'will flow through pipe-H and tubes 14 into the Weigh jars.

The-milk received in the receiving tank 65 will be at substantially body temperature and it is found thatthere is little drop in temperature even though milk is retained therein for two or three hours. If, however, it is desired to maintain the milkexactly at body temperature the receiving'tank may be suitably jacketed for the reception of warmwater for this purpose.

Fig. 2 illustrates an apparatus wherein the raw milk atsubstantiallybody temperature and withoutcontact with air may be homogenized, pasteurized, cooled and bottled to provide grade A milk as discussed above. Thereceiving tank 65 in Fig; 2 may be the'sametank as the receiving processing plant.

' homogenzation, pasteurization, etc. is to be carried on at a point remote from the dairy farm, then of course, the receiving tank 65 of Fig. 1,

will be portable as shown in Fig. 3, and will receive the milk directly from the weigh jars, and

at the completionof the milking will be taken to a central processing'plant where the milk it contains will be drawn into a vacuum weigh tank and then into a stationary vacuum tank 65 in the Raw milk at substantially body temperature and out of contact with air is withdrawn from the receiving tank 65 through connection 83, valve 85. pipe90 and the inlet? of a conventional homogenizer 92. After the milk is homogenized in the homogenizer 92 it is discharged through the outlet connection 93 into pipe 95. The adjusting handle 94 may be utilized for adjusting the homogenizing pressure and it is found that the ...raw milk is thoroughlyhomogenized at. a presthe raw milk from the receiving tank 65 without contact with air, homogenize the same and The homogenized milk then traverses a pre-heater 96 and is conveyed by a pipe 91 to a heater or pasteurizer 98 where the homogenized milk is heated at least to pasteurization temperatures. From the heater or pasteurizer 98 the pasteurized milk passes through a pipe 99 and T fitting I to a holding valve consisting of pipe IIII, I02, well fitting I03 and pipes I04, I05 and I06. The size, diameter and lengths of the pipes of the holding valve are such that it takes at least seconds for the homogenized, pasteurized milk to pass therethrough. The pasteurized milk is then conveyed from the holding valve through the well fittings I01 and I06 and pipe I09 to a diversion valve III]. The diversion valve operates automatically to direct the flow of milk to a conduit I I5 or to a conduit I20. The conduit I I5 conveys the milk toa conventional milk cooler such as- :an aerator cooler H6 and the cooled milk then entersthe milk feed chamber II I of aconventional bottle filling and capping machine H8 for filling bottles or containers I I9.

The other conduit I operates to convey the milk back to the receiving chamber 65 in the event that the milk is not properly pasteurized. The end of the conduit I20 in the receiving tank 65 may be provided with a suitable strainer like the strainer I2 described above.

. The pre-heater, pasteurizer, holding valve and diversion valve may be suitably supported by a supporting frame I22 which is preferably of open construction so that free access to all of the devices carried thereby may be had. e

I The heater or pasteurizer 96 may be of the construction disclosed and claimed in my copending application Ser. No. 742,673 filed April 19, 1947 and which is'illustrated in Fig. 6 hereof. It includes an outer casing I25 having a steam jacket I26 and an inner sleeve welded into the outer casing. A tapered core I2'I with an internal steam jacket I29 and provided with exterior helical grooves I28, fits the sleeve I21. The milk to be pasteurized enters the pasteurizer through the pipe 91 and flows along the helical grooves I28 byfthe pumping. action of the homo enizer 82 andispasteurized by the steam presentfin the steam chambers I26 and.I29. Steam enters the chamber I 26 through pipe I30 and disdeliver the homogenized raw milk to the pipe 95.

charges therefrom through pipe I3I. Steam also enters into the chamber I 29 through pipe I32, passage I33 and pipe I34, and is discharged therefrom through passage I35 and pipe I36. By reason of the construction of this pasteurizer the milk is brought quickly up to pasteuriz'ing temperature and as it passes through the pasteurizer it does so at high velocity with considerable centrifugal force imparted thereto. This fast moving milk with the forces imparted thereto operates to keep the fat globules thoroughly in suspension, a secondary homogenization action at low pressure; and the high degree of turbulence in the milk or cream passing through the spiral groove at high velocity and with centrifugal action, effectively prevents fbllrning on of the milk. This is one of the factors which provides the milk withhigh heat stability and at the same time prevents the formation of pasteurized or cooked flavors. Thepre-heater 96 maybe of the same construction as thepasteurizer and may operate in the same manner. The pre-heater will raise the temperature of the raw homogenized milk up to about whereupon themilk is raised from that temperature to the pasteurizing temperature of at least F. by the pasteurizer.

The manner of'supplying steam to the hasteurizer and pre-heater is illustratedin Fig. 4.

Here the steam is supplied from the steam header I40 through valve MI and pipe I43 containing a pressure reducing ,valve I44, a pressure gauge I45 and a thermostatically operated valve I46. The steam fromthe pipe I43 enters the heater or pasteurizer 98 through pipes I32 and I30 and is exhausted therefrom through pipes I 3| and I36 to pipe I41. The exhaust steam in pipe I4'I from the pasteurizer 91 then flows through pipes I30 and I32 into the pre-heater 96 and exhausts therefrom through pipes I3I and I 35 into pipe I 48 and thence through a steam trap I49 to the exhaust steam header I49. Thus the live steam regulated as to pressures and flow first enters the pasteurizer for pasteurizing purposes and then the exhaust steam from the Desteurizer enters the pre -heater for .pre-heating Thus, economy of steam is provided Referring again to Fig. 2, the diversion valve I I0 is operated by an air motor I55 which in turn is controlled by a solenoid valve I56. The solenoid valve controls the supply of air from an air supply pipe I51 to a control pipe I58 connecting the solenoidvalve with the air motor. When the solenoid valve is energized, air is supplied to the air motor I 55 to maintain the diversion valve H0 in a lowered position whereby the milk from the holding valve is conveyed through the milk conduit H5. The solenoid valve I56 is suitably electrically connected by wires I59 to a control switch in a conventional thermometer controller I60 having a'capillary tube I6 I connected to a thermometer bulb I62 located in the well fitting I08.

thermostatically controlled d Se lone a t e t m r tur o the mil flo n from the h din ethr us th -We1lfi t n 4. 8.11 a 0.1. he a e r at eh tem er tu the thermometer controller lfiii rnaintains the e ehei valve ene i d to direc the flo 9 pa eurized milk h ough t e l con Hl'r-v I o er-the tem r tur o e m at the well fitting "18 should decrease belowpasteurization temperature, then the solenoid valve I 56. is de-energized by the thermometer controller i60-whereupon the air motor I55 is operated to; move the diversion-valve H9 upwardly. As; a result, the milk tromthe holding valve is d ve ted h ush' h ne J20 h e s i to t r .ee v hsta 5 ersi jba -t thereee vin a k 5 wi cont nu unti th em er ee he m lk-a the el fitt ng Q etu n th ras u zln tem e a ur o at lea 1166? Wh ere t r ins temper re i a n t n th dl eli eh lve "HEB il b chew d un er the ent a t e ther m er :QQFIFIOHH 1. 9 di c the asteur ed m l threh t emi rien it 1 1: lBy -.-reasen of th ive s n v lve and h holding a e p euriza on .o th m lk a thermometer .164 may becontained within the well fitting .lM-for giving ayisible indication of the asteurizing temperature.

W l the ap atus of; F g. 2 ha b n explainedin connection with..-a .pas teurizing temheretur ei 16 .E- ehvieusl it ma pera at h her e s r ins tempe atur s f xam at .190". n ord r to Pre u e su er steu ed milk hav ng hi h: heati tah lit an other q alities discussed above.

The apparatus illustratedin E'ig. 9 is substantially the .sameas thatillustratedin Fig. 2 and like reference characters have beenutilized for indicating like parts. The apparatus of Fig. 9

.differs from that of Fig. 2 by utilizing adifierent type of pre-heater, cooler andpackaging mechanism; The same heater or pasteurizer 98 is utilized but herethe pre-heater is designated at H0 andthe'cooler-at Hi. The homogenized milk from the homogenizer 92 flows through pipe 95, through the pro-heater I and then through e 91 and th h ate r p ste ri e t h in and di s en a ves h m k. o i H5 from the diversion valve. LIB conveys the pasteurized milk to the pro-heater I10 for the purpose of pre-heatingthe rawhomogenized milk and pro-cooling the pasteurized milk. Theprecooled pasteurized milk then flows through pipe H2 through the cooler I fH and lhence through pipe us to the-milk supply :chamber are to a canning machine J15,

The canning machine may include mechanism tor-maintaining the milk therein under vacuum or under apositive -gas, pressure of nitrogen or siarb n o id er he p r s -Qt. p ng. he nr l put o on a wi hai tma a p vide mean ,.f co ey n t c ns an the lids through a tank of boiling water'before entering s uhject; to sterilizationtemperatures will last indefi tely. The. milk may hesterilized by heatin the-fi led ti s to ster lization. t mperatures.

The milk cooler L1 I may. heof the same general constmctionas the heater or pasteurizerfifi but .insteadefvine st am appliedthereto t will be up l ed with a coo in medium. s c as cold pr c f r meansfqr .directexn nsion. lrefrigeliw -t ent isioundthatto o tain then peri re of cooling, the cooler 'l 1] must. be dimensionally larger than the 'past uri e flfl.

Th p erh a r I10, may .be in then ture of a regenerator and; may be of the type shown and. :described in my co-pending application Ser. No. 55,146 filed October 18, 1948. Such a pre-heater .or regenerator is illustrated inFig. 1 0. The re- .generator comprises a tube 220 of standard external. diameter and ,an internal tube 221. The innertube isi-of therequired thickness to receive external parallel spiral grooves 223 and 224. At each end ofthe tubularcore 221, there are annular heads 22B seated in recesses formed in the ends ,ofthetube 22]. This tube is tapered on the outside .from end to end and it has the spiral grooves zgt, and 224 in its outer diameter that are, sen rat d'hy .a .sn rald i g wall The tuh .22? his .intethe outer ub 28 w c s reyersely tapered on itsinsidediameter to closely fit he'spiral wall. 229 ofthetube 221. There is ane trance to groove 223 through pipe 22l and arreggit throughpipe 225. The direction of flow i n the groove ishindicated 'by the arrows. All ent anceto'the adjacent groove 224 is through pi, JZZ K n th xit'i throush pipe 2.22. Th rer e osejfit b e th outside d ameter at the dividing walls 229 andthe insidetaper offthe outside tube 220 is suchthat there is no mixing of pasteurized milk flowing in one groove with unpasteurized milk inan adjacent groove. There is suihcient length of the grooves to secure the neutralization in temperature of the two milks that are being treated; or, the complete cooling of the milk where milk is circulated in one groove and a cooling medium is circulated in the other groove in reverse direction. The heads 228 are held place by clamps 230 which clamps are pivoted to the outer tube 220 in any desired manner.

As pointed out abovetheapparatus illustrated in Fig, 1 may be located ata farm for-performing the first part of thefmethodand' the apparatus illustrated in Figs. '2 and 9 maybe located ata processingplant for performingthe second part o f v the method. Under these circumstances, itis necessary to transport with the least arnountfoi handling and in the absence of air and without a material drop in t mperatu raw milk m the dairy farm t th proc ssin p nt and it .is extremely. esirable that such transferloe accomplished quickly, within three hours or so. Fig. 3 illustrates a portable. tank arrangement which may be utilized. for accomplishing this transfer.

tank may, also, be provided with a discharge pipe 201 controlled by a, valve 208. The tank may, also, carry a vacuum pump 209 driven by a motor 2I0. The vacuum pump is connected into the tank by means of a valve 2 and may be connected to an external pipe by a valve 2I2. In stead of the portable tank being provided with a'vvacuum pump for maintaining a, vacuum while enroute, the tank may be charged with an inert gas before leaving the. farm. The type of portable tank shown in Fig. 3 need not be used. It

could be an upright tank supported on two wheels, suitable for attaching to an automobile for conveyance to the processing plant.

In order to fill the tank, the vacuum pump is I operated and the valve 2II is opened to create a vacuum within the tank 200. A connection is then made, between the valve 205 and milk line H conveying milk from the weigh jars in the adjoining milking parlor.

If the portable tank is charged with an inert gas for conveyance to the processing plant then the vacuum pump 209-2I0, for creating a vacuum in the-portable tank 200 as through valve 2I2 may be eliminated. One suitable way for introducing an inert gas would be to lead the delivery pipe from the gas cylinder to tap into sanitary line 1I, so that the gas would contact the milk in route from the weigh jars to the portable tank. The warm milk would absorb some of this gas-particularly the fat globules. Fat globules would absorb 13 times as much 002 as nitrogen.

The tank may then be readily and rapidly transported to the processing plant for discharging the milk into a weigh tank and then into the tank 65 of Fig. 2. When this is done the valve 208 is suitably connected to the receiving. or weigh tank at the processing plant. The portable tank is placed at the central processing plant in a position for the milk to be drawn into the vacuum weigh tank by gravity, where the weight and test of the incoming milk is secured. The weigh tank will also be under vacuum created by the vacuum pump at the processing plant. From the weigh tank the milk will be drawn into one of the storage tanks by either gravity or vacuum of a higher degree than that in the weigh tank. In any event the milk will be in the supply tank under either vacuum or inert gas so that it is notin contact with air. q

Since one of the essential steps of this process is to process the milkbefore it is cooled it may be necessary to either insulate the portable tank or provide it with a water jacket and means for maintaining the milk at or near body temperature in transit.

In the method of canningthe milk as disclosed in Fig. 9 the milk is homogenized, pasteurized at relatively high temperatures and then filled and sealed in cans either under vacuum or in'an atmosphere of an inert gas. The filled cans are then subjected to a suitable temperature to bring about complete sterilization of the milk therein. Sterilization temperatures ranging from'240? to 260 F. and relatively short holding times have proven quite successful. It is found that high sterilization temperatures with short holding times result in a milk with less heated flavor. A high sterility withthe least possible heated flavor may be attained by pre-heating and pasteurizing the milk at a fairly high temperature, approximately 250, which raises the temperature very rapidly while the milk is under great turbulence, then by promptly and rapidly again raising the temperature to approximately290 or 300 F. followed immediately thereafter by rapidly cooling to approximately 100 F. The milk treated in this fashion may then be aseptically canned and sealed and then further cooled to about 40 to 50 F. This operation is preferably performed in a closed system without exposure to air.

Figure 11 diagrammatically shows themanner in which this process of treating and canning the milk may be accomplished without special equipment. The arrangement of Fig. 11 corresponds generally to that of Fig. 9 and like reference characters have beenutilized for likeparts. In Fig. 11 the warm milk to be processed is in the tank 65 at a temperature of to F. and the milk is preferably blanketed with an inert gas such as nitrogen or carbon dioxide. The homogenizer 92 pulls the milk from the tank 65 and homogenizes it at approximately 2,000 lbs. per square inch and forces the milk through the pre-heater or regenerator I10 where it is heated to substantially 190 F. bythe hot milk flowing in the opposite direction. The pre-heated homogenized milk then flows through the heater or pasteurizer 9-8, the holding valves IOI, I04, I06

and into the diversion valve IIO. If it is not up to the required temperature of substantially 250 F. it will be diverted back to the tank 65, but if it is up to that temperature it will go forward to an intermediate tank 300. This tank 300 is preferably smaller than'the tank 65' and is under suitable pressure of an inert gas at about 30 to 40 lbs. per square inch to prevent the milk from boiling. From the tank 300 the milk is immediately withdrawn by a second homogenizer 92' or a suitable positive pressure pump having the same pumping capacity as the first homogenizer. The second homogenizer 92 forces the milk through a pipe 30I and a second heater or pasteurizer 98 to bring the milk up to the final sterilization temperature of about 290 to 300 F. The milk then passes through the holding valves IOI', I04, I06 to the diversion valve Hi). If the milk is not at the desired temperature of substantially 290 to 300 F. it is diverted back to the intermediate tank 300. If it is up to that temperature the milk then passes through pipe 302 and through the heat exchanger or regen erator I10 wherein thesterilized milk is cooled and the raw homogenized milk is heated by heat exchange therein. From the regenerator I10 the partially cooled milk flows through pipe I12 to a cooler I11 where its temperature is substantially lowered to about 100 F. From the cooler I1I the sterilized milk flows through pipe I13 to the supply chamber I14 of a canning machine I15. I

The milk in the supply chamber I14 is fed into cans that are filled and sealed in the chamber 301 which is under positive pressure of an inert gas. Cans and lids therefor are conveyed to the canning machine I15 by a, conveyor 305 and pass through a chamber 300 where'they are subz-crasoc 1,5 jected to. the sterilizing effects of boiling water or steam before they enter the'filling chamber 301. In this way the sterilized milk is aseptically canned. The aseptically canned milk is then conveyed through a tank 308 of flowing cold water where the canned milk is cooled to substantially 40 to 50 F.

Thus the milk by a continuous process is homogenized, subjected to a pro-heating temperature and pasteurized, held the required few seconds in the first holding valve, subjected to the final sterilization temperature, held the required few seconds in the second holding valve, cooled continuously in two steps in the regenerator and cooler before being asepticallycanned and sealed, and then finally cooled in the cans. Instead of cooling the sterilized milk before it is canned, the cans may be filled and sealed with milk while at the sterilizationtemperature .and the cooling of themilk may lie-accomplished after it is sealed in the cans. If. thislatter method is utilized asepticcanning of the sterilized milk is not required.

There, therefore, are generally three ways of completing the canning and sterilization of the low oxygen, non-enzymatic milk of this invention, i. e., (l) by pasteurizing'the milk, filling and sealing'the cans with the milk and then subjecting the canned milk to the final sterilization temperatures as illustrated in Fig. 9, (2) by pasteurizing the milk, subjecting the milk to a substantially sterilizing temperature, partially cooling the sterilized milk, aseptically canning the milk and finally cooling the milk in the cans as disclosed in connection with Fig. 11 and (3) by pasteurizing theh milk, subjecting the milk to substantially sterilizing temperature, filling and sealing the cans while the milk is at the sterilizing temperature and doing the cooling after the milk is sealed in the cans, also as described in connection with Fig. 11. By methods 1 and 3 aseptic canning is not necessary though canning in an oxygen free atmosphere'is required. In these two methods the cans and lids might carry some bacteria, but these would be killed by the high temperatures in raising the milk to sterilization temperature in the'can or by filling the cans with milk at sterilization temperature. In the second method aseptic canning is absolutely necessary otherwise the sterilized milk may be reinfected in the canning process. The second method, however, results in less heated flavor since the heating and cooling of the milk is very rapid.

While for urposes of illustration, several forms of this invention have been disclosed, other forms thereof may become apparent to those skilled in the art upon reference to this disclosure, and therefore, this invention is to be limited only by the scope of the appended claims and prior art.

I claim:

1. The method for processing milk comprising withdrawing milk from a cow without contact with air, collecting the withdrawn raw milk without contact with air and maintaining the same substantially at body temperature, homogenizing under super-atmospheric pressure the collected raw milk without substantial prior cooling and without contact with air, and promptly and rapidly heating the homogenized milk without contact with air at least to pasteurization temperatures.

2. The method for processing milk comprising withdrawing milk from a cow without contact with air, collecting the withdrawn raw milk without contact. with air and maintaining the same. substantially'at body temperature, homogenizing under super-atmospheric pressure the collected raw milk without substantial prior cooling and without contact with air, and promptly and rapidly heating the homogenized milk without contact with air to sterilization temperatures to sterilize the same.

3. The method for processing milk comprising withdrawing milk from a cow Without contact with air, collecting the withdrawn raw milk without contact with air and maintaining the same substantially at body temperature, homogenizing under super-atmospheric pressure the collected raw milk without substantial prior cooling and without contact with air, promptly and rapidly heating the homogenized milk without contact with air at least to pasteurization temperatures to pasteurize the same, cooling the heated homogenized milk, and filling containers with the cooled homogenized milk.

,4. The method for processing milk comprising withdrawing milk from a cow without contact with air, collecting the withdrawn raw milk without contact with air and maintaining the same substantially at body temperature, homogenizing under super-atmospheric pressure the collected raw milk without substantial prior cooling and without contact with air, promptly and rapidly heating the homogenized milk without contact with air to sterilization temperatures to sterilize the same, promptly, rapidly and aseptically cooling the homogenized sterilized milk without contact with air, and aseptically filling sterile containers with the cooled homogenized sterilized milk and hermetically sealing the same without contact with air.

5. The method for processing milk comprising withdrawing milk from a cow without contact with air, collecting the withdrawn raw milk without contact with air and maintaining the same substantially at body temperature, homogenizing under super-atmospheric pressure the collected raw milk without substantial prior cooling and without contact with air, promptly and rapidly heating the homogenized milk without contact with air-at least to pasteurization temperatures, filling containers with the heated homogenized milk and hermetically sealing the same without contact with air, and heating the hermetically sealed containers to sterilization temperatures for sterilizing the homogenized milk therein.

6. The method for. large production processing of milk obtained from a plurality of farms comprising withdrawing from each of a plurality of cows at each or a plurality of farms raw milk without contact with air, separately collecting the withdrawn raw milk from each cow in weigh jars without contact with air, collecting at each farm the withdrawn raw milk of each cow from the weigh jars of thatrarm in a common portable tank for each farm without contact with air and substantially at body temperature, transporting from each farm to a central processing plant in the portable tanks of each farm. the collected raw milk without contact with air and substantially at body temperature, collecting at the central processing plant the raw milk from the portable tanks into storage tanks Without contact with air and substantially at body temperature, withdrawing from the storage tanks and homogenizing under super-atmospheric pressure the collected raw milk without substane tin prior cooling and without contact. with-air,

and promptly and rapidly heating thehomogenized milk without contact with air atleast to pasteurization temperatures;

7. The method for large production processing of milk obtained from a plurality of farms come prising withdrawing from each of a pluralityof cowsat each of a plurality of farms raw milk without contact with air, separately collecting the withdrawn raw milk from each cow in weigh jars without contact with aim-collecting at each farm the withdrawn raw milk of each cow-from' the weigh jars of that farm in a common port-- able tank for each farm without contact with air and substantially at body temperaturetrans porting from each farm to a central processing plant in the'portable tanks of each farm the col-- lected raw milk without contact with air andsubstantially at body temperature, collecting-at the central processing plant theraw milk' from the portable tanks into storage tanks' without contact with air and substantially at "body tem perature, withdrawing from the storage tanks and homogenizing under super-atmosphericpressure the collected raw milk without sub-- 7 stantial prior cooling and without contact with air, and promptly and rapidly heating the ho-' mogenized milk without contact with air to sterilization temperatures to'sterilize the same;

8. The method for large production processing of milk obtained from a plurality of farms com-- prising withdrawing from each of a plurality of cows at each of a plurality of farms raw milk;

without contact with air, separately collecting the withdrawn raw milk from each cow in weigh jars without contact with air, collecting at each farm the withdrawn raw milkof each cow from the weigh jars oi that farm in a common portable tank for each farm without contact with air and substantially at body temperature, transporting from each farm to a central processing plant in the portable tanks of each farm the collected raw milk Without contact with air and substantially at body temperature, collecting at the central processing plant the raw milk from the portable tanks into storage tanks without contact with air and substantially at body temperature, withdrawingfrom the storage tanks and homogenizing under super-atmospheric pressure'the col:

sterile containers with' the cooled homogenized sterilized milk and hermetically sealing the same without contact with air.

9; A milk processing apparatus for processing raw milk which has not been contacted by air,

nor subjected to substantial prior cooling comprising an enclosed tankcontaining said raw milk out of contact with air, a homogenizer for homogenizing said raw milk under super-at mospheric pressure Without contact with air,,a

milk connection between the tank and the homoge enizer for supplying said raw milk to the homogenizer, an enclosed continuous flow heaterior rapidly heating the homogenizedraw milk at.

least to pasteurization temperature without con:-

tactgwith air, a milk connection between-the homogenizer and the heater for supplying under:

super-atmospheric pressure homogenized milk w to' the heaterfor rapid circulation through; the heater by thehomogenizer, and a milk connection from the heater for the heated homogenized milk. 1

10. A milk processing apparatus for processing raw milk :whichhas not been contacted by air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out of contact with air, a homogenizer for homogenizing said raw milk under super-atmospheric pressure without contact with air, a milk connection between the tank and the homogenizer for supplying saidraw milk to the homogenizer, an enclosed continuous flow heater for rapidly heating the homogenized raw milk to sterilization temperatures without contact with air to sterilize the samega milk connection between thehoniog'enizer and the heater for supplying under super-atmospheric pressure homogenized milk to th'e heater for rapid circulation through the heater by the homogenizer, and a milk connection-from the heater for the heate homogenized milk.

1-1. A milk processing apparatus for processing rawmilk which has not been contactedby air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out of contact with air, a homogenizer for homo enizing said raw 1 milk under super-atmospheric pressure 'withoutcontact with air, a milk connection between the tank and the homogenizer for supplying said raw milk to the homogenizer, an enclosed'continuous flow heater for rapidly heating the homogenized raw milk at least to pasteurization temperature without contact with air, a milk connection between the homogenizer and the heater for supplying under super-atmospheric pressure homogenized milk to the heater for rapid circulation through the heater by the homogenizer, an enclosed continuous flow cooler for rapidly cooling the heated homogenized milk without contact with, air, a milk connection between the heater and the cooler for supplying the heated homogenized milk to the cooler for rapid circulation through the cooler by the homogenizer, a receptacle filling machine, and a milk connection between the cooler and the filling machine for, supplying cooled homogenized milk to the'filling machine, a

12 A' milk processing apparatus for processing raw milk which has not been contacted by air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out. of contact with air, a homogenizer for homogenizing said raw milk under super-atmospheric pressure without contact with air, a milk connection between thetank and the homogenizer for supplying said raw milk to the homogenizer, an enclosed continuous flow heater for rapidly heating thehornogenized raw milk to sterilization temperatures withoutcontact with air to sterilize the same, amilk connection between the homogenizer and the heater for supplying under superatmospheric pressure homogenized milk to the heater for rapid circulation through theheater by the homogenizer, an enclosed continuous flow cooler; for. rapidly cooling the sterilized homogenized milk without contact with air, a milk connection between the heater and the cooler for supplying the sterilized homogenized milk to the cooler for rapid circulation through the cooler by the 'homogenizer, an aseptic canning machine for aseptically canning the cooled sterilized homogenized milk without contact with air,

and a milk connection between the cooler and the canning machine for supplying cooled sterilized homogenized milk to the canning machine for aseptic canning thereby.

13. A milk processing apparatus for processing raw milk which has. not been contacted by air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out of contact with air, a homogenizer ior homogenizing said raw milk under super-atmospheric pressure without contact with air, a milk connection between the tank and the homogenizer for supplying said raw milk to the homogenizer, an enclosed continuous flow heater for rapidly heating the homogenized raw milk at least to pasteurization temperature without contact with air, a milk connection between the homogenizer and the heater for supplying under super-atmospheric pressure homogenized milk to the heater for rapid circulation through the heater by the homogenizer, an enclosed continuous flow cooler for rapidly cooling the heated homog enized milk without contact with air, a milk connection including a holding valve portion between the heater and the cooler for supplying the heated homogenized milk to the cooler for rapid circulation through the cooler by the homogenizer, a receptacle filling machine, a milk connection between the cooler and the filling machine for supplying cooled homogenized milk to thefilling machine, a diversion valve in the milk connection between the heater and the cooler, and control means responsive to the temperature of the heated homogenized milk in the holding valve portion of said connection containingthe diversion valve for controlling the diversion valve to divert the flow of heated homogenized milk from the cooler when the temperature falls below a predetermined value.

14. A milk processing apparatus for processing raw milk which has not been contacted by air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out of contact with air, a homogenizer for homogenizing said raw milk under super-atmospheric pressure without contact with air, a milk connection between the tank and, the homogenizer for supplying said raw milk to the homogenizer, an enclosed continuous flow heater for rapidly heating the homogenized raw milk to sterilization temperatures without contact with air to sterilize the same, a milk connection between the homogenizer and the heater for supplying under superatmospheric pressure homogenized milk to the heater for rapid circulation through the heater by the homogenizer, an enclosed continuous flow cooler for rapidly cooling the sterilized homogenized milk Without contact with air, a milk connection including a holding valve portion between the heater and the cooler for supplying the sterilized homogenized milk to the cooler for rapid circulation through the cooler by the homogenizer, an aseptic canning machine for aspectically canning the cooled sterilized homogenized milk without contact with air, a milk connection be tween the cooler and the canning machine for supplying cooled sterilized homogenized milk to the canning machine for aseptic, canning thereby, a diversion valve in the milk connection between the heater and the cooler, and control means responsive to the temperature of the heated homogenized milk in the holding valve portion of said connection, containin the diversion valve for controlling the, diversion valve to.- dive t fl w o eated omosenizedmilkfrom.

20 the cooler when the temperature falls below a predetermined value.

15; A milk processing apparatus for processing raw milk which has not been contacted by air nor subjected to substantial prior cooling comprising an enclosed tank containing said raw milk out of contact with air, a homogenizer for homogenizing said raw milk under super-atmospheric pressure without contact with air, a milk connection between the tank and the homogenizer for supplying said raw milk to the homogenizer, an enclosed continuous flow preheater for rapidly preheating the homogenized milk without contact with air, a milk connection between the homogenizer and the preheater for supplying under super-atmospheric pressure homogenized milk to the preheater for rapid circulation therethrough by the homogenizer, an enclosed continuous flow heater for rapidly heating the preheated homogenized milk at least to pasteurization temperatures without contact with air, a milk connection between the preheater and the heater for supplying under super-atmospheric pressure preheated homogenized milk to the heater for rapid circulation therethrough by the homogenizer, and a milk connection from the heater for the heated homogenized milk.

16. The method for processing raw milk which has. not. been contacted by air nor subjected to substantial prior cooling comprising homogenizing under super-atmospheric pressure said raw milk without substantial cooling and without contact with air, and promptly and rapidly heating the homogenized milk without contact with air at least to pasteurization temperatures.

17, The method for processing raw milk which has not been contacted by air nor subjected to substantial prior cooling comprising homogenizing, under super-atmospheric pressure said raw milk without substantial cooling and without contact. with air, and promptly and rapidly heating the homogenized milk without contact with air to sterilization temperatures to sterilize the same.

18. The method for processing raw milk which has not been contacted by air nor subjected to substantial prior cooling comprising homogenizing under super-atmospheric pressure said raw milk without substantial cooling and without contact with air, promptly and rapidly heating the homogenized milk without contact with air at least to pasteurization temperatures to pasteurize the same, cooling the heated homogenized milk, and filling containers with the cooled homogenized milk.

19. The method for processing raw milk which has not beenv contacted by air nor subjected to substantial prior cooling comprising homogenizing under super-atmospheric pressure said raw milk without substantial cooling and without contact with air, promptly and rapidly heating the homogenized milk without contact with air tosterilization temperatures to sterilize the same, promptly, rapidly and aseptically cooling the ho- .mogenizedsterilized milk without contact with tactv with air, promptly and rapidly heating the 21' i. a homogenized milk without contact with air at least to pasteurization temperatures, filling containers with the heated homogenized milk and hermetically sealing the same without contact with air, and heating the hermetically sealed. containers to sterilization temperatures for sterilizing the homogenized milk therein.

ROY "R. GRAVES.

REFERENCES CIT D The following references are of record in the tile of this patent:

Number 22 UNITED STATES PATENTS Name Date Graves Mar. 31, 1931 Martin, Jr Sept. 29, 1931 Stephens Oct. 18, 1932 Graves Oct. 16, 1934 Horneman Sept. 30, 1938 Grindrod Aug. 22, 1939 Russel Dec. 31, 1940 North et a1 Apr. 22, 1941 Thomas Aug. 19, 1947 Olson et a1 Sept. 19, 1950 

1. THE METHOD FOR PROCESSING MILK COMPRISING WITHDRAWING MILK FROM A COW WITHOUT CONTACT WITH AIR, COLLECTING THE WITHDRAWN RAW MILK WITHOUT CONTACT WITH AIR AND MAINTAINING THE SAME SUBSTANTIALLY AT BODY TEMPERATURE, HOMOGENIZING UNDER SUPER-ATMOSPHERIC PRESSURE THE COLLECTED RAW MILK WITHOUT SUBSTANTIAL PRIOR COOLING AND WITHOUT CONTACT WITH AIR, AND PROMPTLY AND RAPIDLY HEATING THE HOMOGENIZED MILK WITHOUT CONTACT WITH AIR AT LEAST TO PASTEURIZATION TEMPERATURES. 